Difference between revisions of "Team:Freiburg/Modeling"

Revision as of 19:25, 9 September 2015 (view source)

Katharinamoos91 (Talk | contribs)

← Older edit

Latest revision as of 00:18, 19 September 2015 (view source)

MaurizioC (Talk | contribs)

(20 intermediate revisions by 3 users not shown)

Line 1:

−

+

<html>

−

+

−

<~~script type="text/x~~-~~mathjax-config">~~

+

−

~~MathJax.Hub.Config({~~

+

−

~~displayAlign: "left"~~

+

−

~~});~~

+

−

~~</script>~~

+

−

~~<script src~~="~~https://2015.igem.org/common/MathJax-2.5-latest/MathJax.js?config=TeX-AMS-MML_HTMLorMML~~">

+

−

~~</script>~~

+

−

+

−

~~<h2> Modeling</h2>~~

+

−

+

−

+

−

~~<div class~~="~~highlightBox">~~

+

−

~~<h4>Note</h4>~~

+

−

~~<p>In order to be considered for the <a href~~="https://2015~~.igem.org/Judging/Awards#SpecialPrizes">Best Model award</a>, you must fill out this page.</p>~~

+

−

~~</div>~~

+

−

+

−

+

−

<p>Mathematical models and computer simulations provide a great way to describe the function and operation of BioBrick Parts and Devices. Synthetic Biology is an engineering discipline, and part of engineering is simulation and modeling to determine the behavior of your design before you build it. Designing and simulating can be iterated many times in a computer before moving to the lab. This award is for teams who build a model of their system and use it to inform system design or simulate expected behavior in conjunction with experiments in the wetlab.</p>

+

−

+

−

~~<p>~~

+

−

~~Here are a few examples from previous teams:~~

+

−

~~</p>~~

+

−

~~<ul>~~

+

−

~~<li><a href="https://2014~~.igem.org/Team:~~ETH_Zurich~~/~~modeling~~/~~overview~~"~~>ETH Zurich 2014<~~/a>~~</li>~~

+

−

~~<li><a href="https://2014.igem.org/Team:Waterloo/Math_Book">Waterloo 2014</a></li>~~

+

−

~~</ul>~~

+

−

+

−

~~<h2> Detailed System</h2>~~

+

−

+

−

~~<h3> Transcription</h3>~~

+

−

+

−

~~<h4> ODE System</h4>~~

+

−

+

−

~~<br>~~

+

−

~~\[ tc0(1): \;\;\; \frac{dc^{RNAP}_{free}[t]}{dt}\: =\: c^{RNAP}_{bound}[t] \cdot k^{RNAP}_{gain} - c^{RNAP}_{free}[t] \cdot k^{RNAP}_{loss} \]~~

+

−

~~\[ \hphantom{tc0(1): \;\;\; \frac{dc^{RNAP}_{free}[t]}{dt}\: =\: } + c^{RNAP}_{sigma}[t] \cdot k^{sigma}_{off} - c^{RNAP}_{free}[t] \cdot c^{sigma}[t] \cdot k^{sigma}_{on} \]~~

+

−

~~\[ \hphantom{tc0(1): \;\;\; \frac{dc^{RNAP}_{free}[t]}{dt}\: =\: } + c^{RNAP}_{elongter}[-1][t] \cdot k^{RNAP}_{diss} \]~~

+

−

+

−

~~<br>~~

+

−

~~\[ tc0(2): \;\;\; \frac{dc^{sigma}[t]}{dt}\: =\: c^{sigma}_{bound}[t] \cdot k^{sigma}_{gain} - c^{sigma}[t] \cdot k^{sigma}_{loss} + c^{RNAPsigma}_{bound}[t] \cdot k^{sigma}_{off} \]~~

+

−

~~\[ \hphantom{tc0(2): \;\;\; \frac{dc^{sigma}[t]}{dt}\: =\: } + c^{RNAP}_{sigma}[t] \cdot k^{sigma}_{off} - c^{RNAP}_{free}[t] \cdot c^{sigma}[t] \cdot k^{sigma}_{on} \]~~

+

−

~~\[ \hphantom{tc0(2): \;\;\; \frac{dc^{sigma}[t]}{dt}\: =\: } + c^{RNAP}_{ini}[-1][t] \cdot k^{tc}_{prel} \]~~

+

−

+

−

~~<br>~~

+

−

~~\[ tc0(3.1): \;\;\; \frac{dc^{RNAP}_{sigmaint}[t]}{dt}\: =\: c^{RNAP}_{free}[t] \cdot c^{sigma}[t] \cdot k^{sigma}_{on} - c^{RNAP}_{sigmaint}[t] \cdot k^{sigma}_{off} \]~~

+

−

~~\[ \hphantom{tc0(3.1): \;\;\; \frac{dc^{RNAP}_{sigmaint}[t]}{dt}\: =\: } + c^{RNAP}_{sigma}[t] \cdot k^{RNAPsigma}_{isore} - c^{RNAP}_{sigmaint}[t] \cdot k^{RNAPsigma}_{iso} \]~~

+

−

+

−

~~\[ tc0(3.2): \;\;\; \frac{dc^{RNAP}_{sigma}[t]}{dt}\: =\: c^{RNAPsigma}_{bound}[t] \cdot k^{RNAP}_{gain} \cdot c^{RNAP}_{sigma}[t] \cdot k^{RNAP}_{loss} \]~~

+

−

\[ \hphantom{tc0(3.2): \;\;\; \frac{dc^{RNAP}_{sigma}[t]}{dt}\: =\: } + \sum \limits_{i=0}^n c^{RNAP}_{on}[i][t] \cdot k^{RNAP}_{off} - c^{RNAP}_{sigma}[t] \cdot p^{DNA} \cdot l^{DNA} \cdot k^{RNAP}_{on} \]

+

−

~~\[ \hphantom {tc0(3.2): \;\;\; \frac{dc^{RNAP}_{sigma}[t]}{dt}\: =\: } + c^{RNAP}_{sigmaint}[t] \cdot k^{sigma}_{iso} - c^{RNAP}_{sigma}[t] \cdot k^{RNAPsigma}_{isore} \]~~

+

−

+

−

~~<br>~~

+

−

~~\[ tc0(4): \;\;\; \frac{dc^{RNAP}_{on}[i][t]}{dt}\: =\: c^{RNAP}_{sigma}[t] \cdot p^{DNA} \cdot k^{RNAP}_{on} \]~~

+

−

~~\[ \hphantom{tc0(4): \;\;\; \frac{dc^{RNAP}_{on}[i][t]}{dt}\: =\: } + c^{RNAP}_{on}[i\:-\:v^{RNAP}_{move} \cdot dt][t] \cdot (1 - k^{RNAP}_{off}) - c^{RNAP}_{on}[i][t] \]~~

+

−

+

−

~~<br>~~

+

−

~~\[ tc0(5): \;\;\; \frac{dc^{RNAP}_{prom}[t]}{dt}\: =\: \sum \limits_{i\:=\:n - v^{RNAP}_{move} \cdot dt}^n c^{RNAP}_{on}[i][t] \cdot (1 - k^{RNAP}_{off}) \]~~

+

−

~~\[ \hphantom{tc0(5): \;\;\; \frac{dc^{RNAP}_{prom}[t]}{dt}\: =\: } + c^{RNAP}_{open}[t] \cdot k^{tc}_{closed} - c^{RNAP}_{prom}[t] \cdot k^{tc}_{open} \]~~

+

−

+

−

~~<br>~~

+

−

~~\[ tc0(6): \;\;\; \frac{dc^{RNAP}_{open}[t]}{dt}\: =\: c^{RNAP}_{prom}[t] \cdot k^{tc}_{open} - c^{RNAP}_{open}[t] \cdot k^{tc}_{closed} \]~~

+

−

~~\[ \hphantom{tc0(6): \;\;\; \frac{dc^{RNAP}_{open}[t]}{dt}\: =\: } + c^{RNAP}_{ini}[-1][t] \cdot k^{tc}_{iniab} - c^{RNAP}_{open}[t] \cdot c^{ATP}[t] \cdot c^{X_1 TP}[t] \cdot k^{tc}_{ini1} \]~~

+

−

+

−

~~<br>~~

+

−

~~\[ tc0(7): \;\;\; \frac{dc^{RNAP}_{ini1}[t]}{dt}\: =\: c^{RNAP}_{open}[t] \cdot c^{ATP}[t] \cdot c^{X_1 TP}[t] \cdot k^{tc}_{ini1} - c^{RNAP}_{ini1}[t] \cdot c^{X_2 TP}[t] \cdot k^{tc}_{inix} \]~~

+

−

+

−

~~<br>~~

+

−

~~\[ tc0(8.1): \;\;\; \frac{dc^{RNAP}_{ini}[i][t]}{dt}\: =\: c^{RNAP}_{ini}[i-1][t] \cdot c^{X_i TP}[t] \cdot k^{tc}_{inix} - c^{RNAP}_{ini}[i][t] \cdot c^{X_i+1 TP}[t] \cdot k^{tc}_{inix}, \]~~

+

−

~~\[ \hphantom{tc0(8.1): \;\;\; \frac{dc^{RNAP}_{ini}[i][t]}{dt}\: =\: } (i = 2, ..., l^{ini-1}) \]~~

+

−

+

−

~~\[ tc0(8.2): \;\;\; \frac{dc^{RNAP}_{ini}[1][t]}{dt}\: =\: \frac{dc^{RNAP}_{ini1}[t]}{dt} \]~~

+

−

+

−

~~\[ tc0(8.3): \;\;\; \frac{dc^{RNAP}_{ini}[-1][t]}{dt}\: =\: c^{RNAP}_{ini}[-2][t] \cdot c^{X_-1 TP}[t] \cdot k^{tc}_{inix} - c^{RNAP}_{ini}[-1][t] \cdot (k^{tc}_{iniab} + k^{tc}_{prel}) \]~~

+

−

+

−

~~<br>~~

+

−

~~\[ tc0(9): \;\;\; \frac{dc^{RNAP}_{prel}[t]}{dt}\: =\: c^{RNAP}_{ini}[-1][t] \cdot k^{tc}_{prel} - c^{RNAP}_{prel}[t] \cdot c^{X_1 TP}[t] \cdot k^{tc}_{elong} \]~~

+

−

+

−

~~<br>~~

+

−

~~\[ tc0(10.1): \;\;\; \frac{dc^{RNAP}_{elong}[i][t]}{dt}\: =\: c^{RNAP}_{elong}[i-1][t] \cdot (1 - prob^{tc}_{mm}) \cdot c^{X_i TP}[t] \cdot k^{tc}_{elong} \]~~

+

−

\[ \hphantom{tc0(10.1): \;\;\; \frac{dc^{RNAP}_{elong}[i][t]}{dt}\: =\: } - c^{RNAP}_{elong}[i][t] \cdot ((1 - prob^{tc}_{mm}) \cdot c^{X_1 TP}[t] \cdot k^{tc}_{elong} + prob^{tc}_{mm} \cdot (c^{NTPs}[t] - c^{X_1 TP}[t]) \cdot k^{tc}_{elong}) \]

+

−

~~\[ \hphantom{tc0(10.1): \;\;\; \frac{dc^{RNAP}_{elong}[i][t]}{dt}\: =\: } + c^{RNAP}_{elongGreAB}[j + l^{mRNA}_{cl}][t] \cdot k^{GreAB}_{cat}, \]~~

+

−

~~\[ \hphantom{tc0(10.1): \;\;\; \frac{dc^{RNAP}_{elong}[i][t]}{dt}\: =\: } (i = 2, ..., l^{elong-1} and j = i and j = 2, ..., l^{elong} - l^{mRNA}_{cl}) \]~~

+

−

+

−

~~\[ tc0(10.2): \;\;\; \frac{dc^{RNAP}_{elong}[1][t]}{dt}\: =\: c^{RNAP}_{prel}[t] \cdot (1 - prob^{tc}_{mm}) \cdot c^{X_1 TP}[t] \cdot k^{tc}_{elong} \]~~

+

−

\[ \hphantom{tc0(10.2): \;\;\; \frac{dc^{RNAP}_{elong}[1][t]}{dt}\: =\: } - c^{RNAP}_{elong}[1][t] \cdot ((1 - prob^{tc}_{mm}) \cdot c^{X_1 TP}[t] \cdot k^{tc}_{elong} + prob^{tc}_{mm} \cdot (c^{NTPs}[t] - c^{X_1 TP}[t]) \cdot k^{tc}_{elong}) \]

+

−

~~\[ \hphantom{tc0(10.2): \;\;\; \frac{dc^{RNAP}_{elong}[1][t]}{dt}\: =\: } + c^{RNAP}_{elongGreAB}[l^{mRNA}_{cl}][t] \cdot k^{GreAB}_{cat} \]~~

+

−

+

−

~~tc0(10.3): \(dc^RNAP_elong[-1][t]/dt = c^RNAP_elong[-2][t] * (1-prob^tc_mm) * c^{X_-1 TP}[t] * k^tc_elong~~

+

−

~~- c^RNAP_elong[-1][t] * l^mRNA * c^pprot * k^pprot_on \)~~

+

−

+

−

~~tc0(11.1): \(d^cRNAP_elongter[i][t]/dt = (c^RNAP_elongter[i-1][t] - c^RNAP_elongter[i][t]) * c^ATP[t] * k^pprot_cat~~

+

−

~~+ c^RNAP_elong[i] * c^pprot * k^pprot_on,~~

+

−

~~(i = 2, ..., l^mRNA-1) \)~~

+

−

~~tc0(11.2): \(dc^RNAP_elongter[-1][t]/dt = c^RNAP_elongter[-2][t] * c^ATP[t] * k^pprot_cat - c^RNAP_elongter[-1][t] * k^RNAP_diss~~

+

−

~~+ c^RNAP_elong[-1][t] * c^pprot[t] * k^pprot_on \)~~

+

−

+

−

~~tc0(12): \(dc^mRNA[t]/dt = c^RNAP_elongter[-1][t] * k^RNAP_diss - c^RNAse_onmRNA[t] * k^RNAse_cat \)~~

+

−

+

−

~~tc0(13): \(dc^RNAP_elongmm[i][t]/dt = c^RNAP_elong[i-1][t] * prob^tc_mm * (c^NTPs[t] - c^{X_1 TP}[t] * k^tc_elong~~

+

−

~~- c^RNAP_elongmm[i][t] * c^GreAB[t] * k^GreAB_on \)~~

+

−

~~tc0(14): \(dc^RNAP_elongGreAB[i][t]/dt = c^RNAP_elongmm[i][t] * c^GreAB[t] * k^GreAB_on - c^RNAP_elongGreAB[i][t] * k^GreAB_cat \)~~

+

−

+

−

~~tc0(15): \(dc^RNAse[t]/dt = c^RNAse_bound[t] * k^RNAse_gain - c^RNAse[t] * k^RNAse_loss~~

+

−

~~+ (c^RNAse_onmRNAcl[t] + c^RNAse_onmRNAab[t] + c^RNAse_onmRNA[t]) * k^RNAse_cat~~

+

−

~~- (c^mRNAcl[t] + c^mRNAab[t] + c^mRNA[t]) * c^RNAse[t] * k^RNAse_on \)~~

+

−

~~tc0(16): \((dc^RNAse_onmRNA[t]/dt , dc^RNAse_onmRNAab[t]/dt , dc^RNAse_onmRNAcl[t]/dt)~~

+

−

~~= c^RNAse[t] * (c^mRNA[t], c^mRNAab[t], c^mRNAcl[t]) * k^RNAse_on~~

+

−

~~- (c^RNAse_onmRNA[t], c^RNAse_onmRNAab[t], c^RNAse_onmRNAcl[t]) * k^RNAse_cat \)~~

+

−

~~tc0(17): \(dc^mRNAab[t]/dt = c^RNAP_ini[-1][t] * k^tc_iniab - c^RNAse_onmRNAab[t] * k^RNAse_cat \)~~

+

−

~~tc0(18): \(dc^mRNAcl[t]/dt = sum \limits_{i=1}^n c^RNAP_elongGreAB[i][t] * k^GreAB_cat~~

+

−

~~+ 2 * c^RNAse_onmRNA[t] * k^RNAse_cat~~

+

−

~~- c^RNAse_onmRNAcl[t] * k^RNAse_cat \)~~

+

−

+

−

~~tc0(19.1): \(dc^entity_bound[t]/dt = c^entity[t] * k^entity_loss - c^entity_bound[t] * k^entity_gain,~~

+

−

~~(entity not in {RNAP, RNAPsigma}) \)~~

+

−

~~tc0(19.2): \((dc^RNAP_bound[t]/dt, dc^RNAPsigma_bound[t]/dt)~~

+

−

~~= c^RNAP[t] * k^RNAP_loss - c^RNAP_bound[t] * k^RNAP_gain~~

+

−

~~+ (c^RNAPsigma_bound[t], -c^RNAPsigma_bound[t]) * k^sigma_off \)~~

+

−

+

−

~~tc0(20): \(dc^pprot[t]/dt = c^pprot_bound[t] * k^pprot_gain - c^pprot[t] * k^pprot_loss~~

+

−

~~+ c^RNAP_elongter[-1][t] * k^RNAP_diss - c^RNAP_elong[-1][t] * l^mRNA * c^pprot[t] * k^pprot_on \)~~

+

−

~~tc0(21): \(dc^GreAB[t]/dt = c^GreAB_bound[t] * k^GreAB_gain - c^GreAB[t] * k^GreAB_loss~~

+

−

~~+ sum \limits_{i=1}^n c^RNAP_elongGreAB[i][t] * k^GreAB_cat~~

+

−

~~- sum \limits_{i=1}^n c^RNAP_elongmm[i][t] * c^GreAB[t] * k^GreAB_on \)~~

+

−

+

−

~~tc0(22): \(dc^NTP[t]/dt = - sum \limits_{i=2, X_i=N}^n c^RNAP_ini[i-1][t] * c^{X_i TP}[t] * k^tc_inix~~

+

−

~~- c^RNAP_prel[t] * (1-prob^tc_mm) * c^{X_1 TP}[t] * k^tc_elong~~

+

−

~~- sum \limits_{i=2, X_i=N}^n-1 c^RNAP_elong[i-1][t] * (1-prob^tc_mm) * c^{X_i TP}[t] * k^tc_elong~~

+

−

~~[- c^RNAP_open[t] * c^ATP[t] * c^X_1 TP[t] * k^tc_ini1]_{for X_1 = N}~~

+

−

~~[-c^RNAP_open[t] * c^ATP[t] * c^NTP[t] * k^tc_ini1~~

+

−

~~- sum \limits_{i=1}^n-1 c^RNAP_elongter[i][t] * c^ATP[t] * k^pprot_cat]_{for N = A} \)~~

+

−

~~tc0(23): \(dc^NTPs[t]/dt = dc^ATP[t]/dt + dc^TTP[t]/dt + dc^GTP[t]/dt + dc^CTP[t]/dt \)~~

+

−

+

−

+

−

+

−

+

</html>

@@ Line 1: / Line 1: @@
-{{Freiburg}}
+{{Freiburg/CSS}}
+{{Freiburg/Menubar}}
 <html>
+<meta http-equiv="refresh" content="0;URL='https://2015.igem.org/Team:Freiburg/Results/Modeling'" />
-<script type="text/x-mathjax-config">
-  MathJax.Hub.Config({
-    displayAlign: "left"
-  });
-</script>
-<script src="https://2015.igem.org/common/MathJax-2.5-latest/MathJax.js?config=TeX-AMS-MML_HTMLorMML">
-</script>
-<h2> Modeling</h2>
-<div class="highlightBox">
-<h4>Note</h4>
-<p>In order to be considered for the <a href="https://2015.igem.org/Judging/Awards#SpecialPrizes">Best Model award</a>, you must fill out this page.</p>
-</div>
-<p>Mathematical models and computer simulations provide a great way to describe the function and operation of BioBrick Parts and Devices. Synthetic Biology is an engineering discipline, and part of engineering is simulation and modeling to determine the behavior of your design before you build it. Designing and simulating can be iterated many times in a computer before moving to the lab. This award is for teams who build a model of their system and use it to inform system design or simulate expected behavior in conjunction with experiments in the wetlab.</p>
-<p>
-Here are a few examples from previous teams:
-</p>
-<ul>
-<li><a href="https://2014.igem.org/Team:ETH_Zurich/modeling/overview">ETH Zurich 2014</a></li>
-<li><a href="https://2014.igem.org/Team:Waterloo/Math_Book">Waterloo 2014</a></li>
-</ul>
-<h2> Detailed System</h2>
-<h3> Transcription</h3>
-<h4> ODE System</h4>
-<br>
-\[ tc0(1): \;\;\; \frac{dc^{RNAP}_{free}[t]}{dt}\: =\: c^{RNAP}_{bound}[t] \cdot k^{RNAP}_{gain} - c^{RNAP}_{free}[t] \cdot k^{RNAP}_{loss} \]
-\[ \hphantom{tc0(1): \;\;\; \frac{dc^{RNAP}_{free}[t]}{dt}\: =\: } + c^{RNAP}_{sigma}[t] \cdot k^{sigma}_{off} - c^{RNAP}_{free}[t] \cdot c^{sigma}[t] \cdot k^{sigma}_{on} \]
-\[ \hphantom{tc0(1): \;\;\; \frac{dc^{RNAP}_{free}[t]}{dt}\: =\: } + c^{RNAP}_{elongter}[-1][t] \cdot k^{RNAP}_{diss} \]
-<br>
-\[ tc0(2): \;\;\; \frac{dc^{sigma}[t]}{dt}\: =\: c^{sigma}_{bound}[t] \cdot k^{sigma}_{gain} - c^{sigma}[t] \cdot k^{sigma}_{loss} + c^{RNAPsigma}_{bound}[t] \cdot k^{sigma}_{off} \]
-\[ \hphantom{tc0(2): \;\;\; \frac{dc^{sigma}[t]}{dt}\: =\: } + c^{RNAP}_{sigma}[t] \cdot k^{sigma}_{off} - c^{RNAP}_{free}[t] \cdot c^{sigma}[t] \cdot k^{sigma}_{on} \]
-\[ \hphantom{tc0(2): \;\;\; \frac{dc^{sigma}[t]}{dt}\: =\: } + c^{RNAP}_{ini}[-1][t] \cdot k^{tc}_{prel} \]
-<br>
-\[ tc0(3.1): \;\;\; \frac{dc^{RNAP}_{sigmaint}[t]}{dt}\: =\: c^{RNAP}_{free}[t] \cdot c^{sigma}[t] \cdot k^{sigma}_{on} - c^{RNAP}_{sigmaint}[t] \cdot k^{sigma}_{off} \]
-\[ \hphantom{tc0(3.1): \;\;\; \frac{dc^{RNAP}_{sigmaint}[t]}{dt}\: =\: } + c^{RNAP}_{sigma}[t] \cdot k^{RNAPsigma}_{isore} - c^{RNAP}_{sigmaint}[t] \cdot k^{RNAPsigma}_{iso} \]
-\[ tc0(3.2): \;\;\; \frac{dc^{RNAP}_{sigma}[t]}{dt}\: =\: c^{RNAPsigma}_{bound}[t] \cdot k^{RNAP}_{gain} \cdot c^{RNAP}_{sigma}[t] \cdot k^{RNAP}_{loss} \]
-\[ \hphantom{tc0(3.2): \;\;\; \frac{dc^{RNAP}_{sigma}[t]}{dt}\: =\: } + \sum \limits_{i=0}^n c^{RNAP}_{on}[i][t] \cdot k^{RNAP}_{off} - c^{RNAP}_{sigma}[t] \cdot p^{DNA} \cdot l^{DNA} \cdot k^{RNAP}_{on} \]
-\[ \hphantom {tc0(3.2): \;\;\; \frac{dc^{RNAP}_{sigma}[t]}{dt}\: =\: } + c^{RNAP}_{sigmaint}[t] \cdot k^{sigma}_{iso} - c^{RNAP}_{sigma}[t] \cdot k^{RNAPsigma}_{isore} \]
-<br>
-\[ tc0(4): \;\;\; \frac{dc^{RNAP}_{on}[i][t]}{dt}\: =\: c^{RNAP}_{sigma}[t] \cdot p^{DNA} \cdot k^{RNAP}_{on} \]
-\[ \hphantom{tc0(4): \;\;\; \frac{dc^{RNAP}_{on}[i][t]}{dt}\: =\: } + c^{RNAP}_{on}[i\:-\:v^{RNAP}_{move} \cdot dt][t] \cdot (1 - k^{RNAP}_{off}) - c^{RNAP}_{on}[i][t] \]
-<br>
-\[ tc0(5): \;\;\; \frac{dc^{RNAP}_{prom}[t]}{dt}\: =\: \sum \limits_{i\:=\:n - v^{RNAP}_{move} \cdot dt}^n c^{RNAP}_{on}[i][t] \cdot (1 - k^{RNAP}_{off}) \]
-\[ \hphantom{tc0(5): \;\;\; \frac{dc^{RNAP}_{prom}[t]}{dt}\: =\: } + c^{RNAP}_{open}[t] \cdot k^{tc}_{closed} - c^{RNAP}_{prom}[t] \cdot k^{tc}_{open} \]
-<br>
-\[ tc0(6): \;\;\; \frac{dc^{RNAP}_{open}[t]}{dt}\: =\: c^{RNAP}_{prom}[t] \cdot k^{tc}_{open} - c^{RNAP}_{open}[t] \cdot k^{tc}_{closed} \]
-\[ \hphantom{tc0(6): \;\;\; \frac{dc^{RNAP}_{open}[t]}{dt}\: =\: } + c^{RNAP}_{ini}[-1][t] \cdot k^{tc}_{iniab} - c^{RNAP}_{open}[t] \cdot c^{ATP}[t] \cdot c^{X_1 TP}[t] \cdot k^{tc}_{ini1} \]
-<br>
-\[ tc0(7): \;\;\; \frac{dc^{RNAP}_{ini1}[t]}{dt}\: =\: c^{RNAP}_{open}[t] \cdot c^{ATP}[t] \cdot c^{X_1 TP}[t] \cdot k^{tc}_{ini1} - c^{RNAP}_{ini1}[t] \cdot c^{X_2 TP}[t] \cdot k^{tc}_{inix} \]
-<br>
-\[ tc0(8.1): \;\;\; \frac{dc^{RNAP}_{ini}[i][t]}{dt}\: =\: c^{RNAP}_{ini}[i-1][t] \cdot c^{X_i TP}[t] \cdot k^{tc}_{inix} - c^{RNAP}_{ini}[i][t] \cdot c^{X_i+1 TP}[t] \cdot k^{tc}_{inix}, \]
-\[ \hphantom{tc0(8.1): \;\;\; \frac{dc^{RNAP}_{ini}[i][t]}{dt}\: =\: } (i = 2, ..., l^{ini-1}) \]
-\[ tc0(8.2): \;\;\; \frac{dc^{RNAP}_{ini}[1][t]}{dt}\: =\: \frac{dc^{RNAP}_{ini1}[t]}{dt} \]
-\[ tc0(8.3): \;\;\; \frac{dc^{RNAP}_{ini}[-1][t]}{dt}\: =\: c^{RNAP}_{ini}[-2][t] \cdot c^{X_-1 TP}[t] \cdot k^{tc}_{inix} - c^{RNAP}_{ini}[-1][t] \cdot (k^{tc}_{iniab} + k^{tc}_{prel}) \]
-<br>
-\[ tc0(9): \;\;\; \frac{dc^{RNAP}_{prel}[t]}{dt}\: =\: c^{RNAP}_{ini}[-1][t] \cdot k^{tc}_{prel} - c^{RNAP}_{prel}[t] \cdot c^{X_1 TP}[t] \cdot k^{tc}_{elong} \]
-<br>
-\[ tc0(10.1): \;\;\; \frac{dc^{RNAP}_{elong}[i][t]}{dt}\: =\: c^{RNAP}_{elong}[i-1][t] \cdot (1 - prob^{tc}_{mm}) \cdot c^{X_i TP}[t] \cdot k^{tc}_{elong} \]
-\[ \hphantom{tc0(10.1): \;\;\; \frac{dc^{RNAP}_{elong}[i][t]}{dt}\: =\: } - c^{RNAP}_{elong}[i][t] \cdot ((1 - prob^{tc}_{mm}) \cdot c^{X_1 TP}[t] \cdot k^{tc}_{elong} + prob^{tc}_{mm} \cdot (c^{NTPs}[t] - c^{X_1 TP}[t]) \cdot k^{tc}_{elong}) \]
-\[ \hphantom{tc0(10.1): \;\;\; \frac{dc^{RNAP}_{elong}[i][t]}{dt}\: =\: } + c^{RNAP}_{elongGreAB}[j + l^{mRNA}_{cl}][t] \cdot k^{GreAB}_{cat}, \]
-\[ \hphantom{tc0(10.1): \;\;\; \frac{dc^{RNAP}_{elong}[i][t]}{dt}\: =\: } (i = 2, ..., l^{elong-1} and j = i and j = 2, ..., l^{elong} - l^{mRNA}_{cl}) \]
-\[ tc0(10.2): \;\;\; \frac{dc^{RNAP}_{elong}[1][t]}{dt}\: =\: c^{RNAP}_{prel}[t] \cdot (1 - prob^{tc}_{mm}) \cdot c^{X_1 TP}[t] \cdot k^{tc}_{elong} \]
-\[ \hphantom{tc0(10.2): \;\;\; \frac{dc^{RNAP}_{elong}[1][t]}{dt}\: =\: } - c^{RNAP}_{elong}[1][t] \cdot ((1 - prob^{tc}_{mm}) \cdot c^{X_1 TP}[t] \cdot k^{tc}_{elong} + prob^{tc}_{mm} \cdot (c^{NTPs}[t] - c^{X_1 TP}[t]) \cdot k^{tc}_{elong}) \]
-\[ \hphantom{tc0(10.2): \;\;\; \frac{dc^{RNAP}_{elong}[1][t]}{dt}\: =\: } + c^{RNAP}_{elongGreAB}[l^{mRNA}_{cl}][t] \cdot k^{GreAB}_{cat} \]
-tc0(10.3):	\(dc^RNAP_elong[-1][t]/dt = 		c^RNAP_elong[-2][t] * (1-prob^tc_mm) * c^{X_-1 TP}[t] * k^tc_elong
-											- c^RNAP_elong[-1][t] * l^mRNA * c^pprot * k^pprot_on \)
-tc0(11.1):	\(d^cRNAP_elongter[i][t]/dt = 	(c^RNAP_elongter[i-1][t] - c^RNAP_elongter[i][t]) * c^ATP[t] * k^pprot_cat
-											+ c^RNAP_elong[i] * c^pprot * k^pprot_on,
-											(i = 2, ..., l^mRNA-1) \)
-tc0(11.2):	\(dc^RNAP_elongter[-1][t]/dt = 	c^RNAP_elongter[-2][t] * c^ATP[t] * k^pprot_cat - c^RNAP_elongter[-1][t] * k^RNAP_diss
-											+ c^RNAP_elong[-1][t] * c^pprot[t] * k^pprot_on \)
-tc0(12):	\(dc^mRNA[t]/dt = 				c^RNAP_elongter[-1][t] * k^RNAP_diss - c^RNAse_onmRNA[t] * k^RNAse_cat \)
-tc0(13): 	\(dc^RNAP_elongmm[i][t]/dt = 	c^RNAP_elong[i-1][t] * prob^tc_mm * (c^NTPs[t] - c^{X_1 TP}[t] * k^tc_elong
-											- c^RNAP_elongmm[i][t] * c^GreAB[t] * k^GreAB_on \)
-tc0(14): 	\(dc^RNAP_elongGreAB[i][t]/dt = 	c^RNAP_elongmm[i][t] * c^GreAB[t] * k^GreAB_on - c^RNAP_elongGreAB[i][t] * k^GreAB_cat \)
-tc0(15):	\(dc^RNAse[t]/dt = 				c^RNAse_bound[t] * k^RNAse_gain - c^RNAse[t] * k^RNAse_loss
-											+ (c^RNAse_onmRNAcl[t] + c^RNAse_onmRNAab[t] + c^RNAse_onmRNA[t]) * k^RNAse_cat
-											- (c^mRNAcl[t] + c^mRNAab[t] + c^mRNA[t]) * c^RNAse[t] * k^RNAse_on \)
-tc0(16): 	\((dc^RNAse_onmRNA[t]/dt , dc^RNAse_onmRNAab[t]/dt , dc^RNAse_onmRNAcl[t]/dt)
-										= 	c^RNAse[t] * (c^mRNA[t], c^mRNAab[t], c^mRNAcl[t]) * k^RNAse_on
-											- (c^RNAse_onmRNA[t], c^RNAse_onmRNAab[t], c^RNAse_onmRNAcl[t]) * k^RNAse_cat \)
-tc0(17):	\(dc^mRNAab[t]/dt = 			c^RNAP_ini[-1][t] * k^tc_iniab - c^RNAse_onmRNAab[t] * k^RNAse_cat \)
-tc0(18): \(dc^mRNAcl[t]/dt = 			sum \limits_{i=1}^n c^RNAP_elongGreAB[i][t] * k^GreAB_cat
-											+ 2 * c^RNAse_onmRNA[t] * k^RNAse_cat
-											- c^RNAse_onmRNAcl[t] * k^RNAse_cat \)
-tc0(19.1):	\(dc^entity_bound[t]/dt = 		c^entity[t] * k^entity_loss - c^entity_bound[t] * k^entity_gain,
-											(entity not in {RNAP, RNAPsigma}) \)
-tc0(19.2): 	\((dc^RNAP_bound[t]/dt, dc^RNAPsigma_bound[t]/dt)
-										= 	c^RNAP[t] * k^RNAP_loss - c^RNAP_bound[t] * k^RNAP_gain
-											+ (c^RNAPsigma_bound[t], -c^RNAPsigma_bound[t]) * k^sigma_off \)
-tc0(20):	\(dc^pprot[t]/dt = 				c^pprot_bound[t] * k^pprot_gain - c^pprot[t] * k^pprot_loss
-											+ c^RNAP_elongter[-1][t] * k^RNAP_diss - c^RNAP_elong[-1][t] * l^mRNA * c^pprot[t] * k^pprot_on \)
-tc0(21):	\(dc^GreAB[t]/dt = 				c^GreAB_bound[t] * k^GreAB_gain - c^GreAB[t] * k^GreAB_loss
-											+ sum \limits_{i=1}^n c^RNAP_elongGreAB[i][t] * k^GreAB_cat
-											- sum \limits_{i=1}^n c^RNAP_elongmm[i][t] * c^GreAB[t] * k^GreAB_on \)
-tc0(22):	\(dc^NTP[t]/dt =				- sum \limits_{i=2, X_i=N}^n c^RNAP_ini[i-1][t] * c^{X_i TP}[t] * k^tc_inix
-											- c^RNAP_prel[t] * (1-prob^tc_mm) * c^{X_1 TP}[t] * k^tc_elong
-											- sum \limits_{i=2, X_i=N}^n-1 c^RNAP_elong[i-1][t] * (1-prob^tc_mm) * c^{X_i TP}[t] * k^tc_elong
-											[- c^RNAP_open[t] * c^ATP[t] * c^X_1 TP[t] * k^tc_ini1]_{for X_1 = N}
-											[-c^RNAP_open[t] * c^ATP[t] * c^NTP[t] * k^tc_ini1
-											- sum \limits_{i=1}^n-1 c^RNAP_elongter[i][t] * c^ATP[t] * k^pprot_cat]_{for N = A}	\)
-tc0(23):	\(dc^NTPs[t]/dt = 				dc^ATP[t]/dt + dc^TTP[t]/dt + dc^GTP[t]/dt + dc^CTP[t]/dt \)
 </html>